Recycling of tires, rubber and other organic material through vapor distillation

ABSTRACT

A processor for vacuum distillation of whole tires including: an insulated housing having a door on one end, a central radiant heat tube and a plurality of peripheral heat tubes spaced about the central radiant heat tube and arranged with an inlet leg of each peripheral heat tube adjacent an outlet leg of another peripheral heat tube to maximize utilization of the radiant heat energy from the peripheral heat tubes. The central radiant heat tube has an unsupported end adjacent the door such that the tires loaded through door will pass over the central radiant heat tube and such that the central radiant heat tube is in a central opening of each tire.

This application is a continuation-in-part of co-pending application Ser. No. 13/199,409, filed Aug. 29, 2011, which is a continuation of application Ser. No. 12/077,795 filed Mar. 21, 2008 and now U.S. Pat. No. 8,038,848, which claims priority from provisional application Ser. No. 60/919,791 filed Mar. 21, 2007.

BACKGROUND OF THE INVENTION

There is a need for effective ways to dispose of waste products in an environmentally safe way. There is a particular need for technologies that will keep material including used tires out of landfills and for processes that will convert materials such as used tires and other waste material otherwise destined for the landfill into useful products or material.

U.S. Pat. No. 5,976,484 is one prior art patent that does show the use of tires as a resource. The tires are cut up and reduced by heat to products such as oil and semi-activated carbon. Prior art systems have been too elaborate and expensive to be commercially practical. In some cases, used tires are just burned for fuel in high energy need processes such as cement kilns. While this provides some value and does keep tires out of dumps and landfills it is still a low value use and requires significant scrubbing of the exhaust gases produced.

As can be seen there is a need for simple and inexpensive ways to reduce the flow of material to landfills. In particular there is a need for processes that will provide better uses for used tire waste and do this in an environmentally safe way.

SUMMARY OF THE INVENTION

According to the invention, a vacuum distillation process is used to reduce tire waste to useful products.

According to the invention, a method of recovering material from tires includes the steps of prepping the tires and weighing the tires to obtain a total tire weight. Then the process monitors the process of tire decomposition by monitoring weight or pressure in the processor. The heating continues until the desired amount of volatiles are driven off and then collected and condensed.

According to another aspect, the invention includes a processor vacuum distillation of whole tires including;

an insulted housing having a door on one end with a plurality of peripheral radiant heat tubes arranged around and spaced from a central radiant heat tube, the central heat tube having an unsupported end adjacent the door such that whole tires loaded on the cart and through the door will pass over the central radiant heat tube such that the central radiant heat tube is located in a central opening of each tire.

These and other advantages of the present invention become apparent from the detailed description of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an overview of the vacuum distillation method;

FIG. 2 shows a flow chart for the vacuum distillation method;

FIG. 3 shows a cross section view of the processor;

FIG. 4 shows details of the heating portion of the processor; and

FIG. 5 shows details of the processor.

FIG. 6 shows details of a vertical loading giant whole OTR tire processor in front section.

FIG. 7 shows details of a vertical loading giant whole OTR tire processor in top section.

FIG. 8 shows details of a horizontally loading giant whole OTR tire processor in side section.

FIG. 9 shows details of a horizontally loading giant whole OTR tire processor in front section.

DETAILED DESCRIPTION OF THE DEVICE

FIG. 1 shows an overview of the vacuum distillation of tires by batch process such as process 100. The process 100 begins with a scale 1 that weighs incoming material 104 such as used tire material. This weight data can be sent to controller 71 for calculating throughput through the processor. Incoming material such as tires can be sent by conveyor 3 to a shredder 5 and then delivered by conveyor 7 to a raw material wash 9. Tires can include whole tires and off the road (OTR) tires. Heater filter 11 can heat and filter wash water for use and reuse in washing dirt and sand from the material 104. Screen 13 allows for dewatering of the washed material and delivers the clean material to a conveyor 15 that carries clean feed material to a loading hopper 17 that is weighed on a scale 19 and delivered to process carts 21 that are loaded with the carcass of used tire material 104. A number of process carts 21 can be loaded into the pre-heater oven 23. Pre-heater oven 23 uses hot exhaust gases from generator 67 to begin to pre heat the tire material 104. Exhaust gas is supplied to the pre-heater through supply line 24. The flow of exhaust gases to pre-heat oven 23 can be controlled by regulator on heat exchanger 26 which in turn can be controlled by a controller 71 according to a target preheat temperature and according to the actual temperature conditions in the oven 23. Exhaust gases in line 24 and 24 a will be at 800-1100 degrees F. and the target pre-heat temperature in pre-heat oven 23 is in the range of 220-300 degrees F. which is high enough to drive off all the water from the washed tire material 104 but well below the temperature range at which any volatile material would begin to come off tire material 104. In addition to exhaust gases from generator 67 fuel from tank 59 can be supplied through line 60 to heater 25. Once controller 71 receives a signal that the pre-heat temperature has been achieved within oven 23 carts 21 will be maintained at that temperature until, carts 21 can be released to the next step. In the main processor 27 the total weight of the carts 21 is known. The carts 21 loaded with materials 104 are weighed using scale 28 and the processor 27 is sealed shut. The materials 104 are then subjected to head and vacuum distillation according to the process flow chart (FIG. 2) or a similar process. For example instead of weight it is known to monitor vacuum distillation based on time and/or pressure readings in a processor which will vary depending on the material being processed.

The tire materials 104 are heated until desired temperatures and vacuum pressures are met to drive off desired volatiles. Initial heat for processor 27 can be provided by exhaust 24 a from generator 67. The exhaust is an ideal starting atmosphere for the processor 27 because it is non-combustible. It is important that the atmosphere in processor 27 be devoid of oxygen as the operating conditions in the processor 27 include temperatures high enough for the materials 104 to ignite. Heat can also be provided by burning gas from line 60 for example. In the processor 27, at relatively low temperatures in the 400-600 degrees F. range, some volatiles in the form of gas will begin to be driven off. A specific target temperature can be set to drive off a known volatile gas and that temperature can be held until all of that material that is volatile at that temperature has been removed through line 29. Gases from line 29 can be supplied to first stage condenser 31. Progress can be monitored by using the scale 28 or other process monitor such as a pressure monitor which can be connected to a programmable controller 71. Desired target temperatures and weights or pressures can be calculated, programmed and stored using the programmable controller 71. The amount of a specific volatile can be known based on knowledge of the tires used and weights taken from scale 28, so the process can proceed until all or a desired percentage of the given volatile has been driven off as monitored by the controller 71. The volatile gas driven off can be pumped into a condenser 31 and desired portions of volatile material can then be condensed out of the gas stream and stored in tank 45. Cooling water for condenser 31 can be supplied by cooling tower 35 or from geothermal or other heat transfer sources. A volatile such as heavy oil can be condensed out of the gas stream from the processor 27, the remaining gas can be stripped off and sent to a further 2^(nd) stage condenser 33. The condensate heavy oil can be pumped by pump 43 to a storage tank 45. A similar separation process occurs again in condenser 33, a further condensate is condensed out at a slightly lower temperature than occurs in condenser 31. In the second condenser 33 a lighter organic is condensed out, in this case a fuel oil might be condensed out and pumped by pump 47 to a second storage tank 49.

The condensation process can be repeated at lower and lower temperatures of condensation to condense out any desired product from the original gas flow from processor 27. At a third stage condenser 37 can even lower temperature of condensation can be provided by chiller 39 and cooling tower 42 further products are pumped off by pump 51. Finally, remaining gas can be pumped by vacuum pump 57 through vacuum surge tank 55 and into stored in the tank 59 to fuel the process. The processor 27 can be controlled to yield different products of vacuum distillation depending upon market demand using programmable controller 71. Once a desired amount of the organics is driven off from the original tire material 104, what remains is steel and carbon char. Depending upon the final heat obtained in the processor 27 will determine the grade of carbon char with some trapped organics remaining.

The processor 27 is capable of driving off some of the contaminants and leaving semi-activated carbon as the final solid. As a practical matter it may be desirable to remove the carbon char from the processor 27 after a lower temperature is achieved and use a separate processor to take it to semi-activated carbon. The processor is a closed system and does not discharge any products to the atmosphere. Char that is structurally sound will come from running the processor 27 at a lower temperature leaving more of the tightly bonded hydrocarbons. As the final temperature in the process rises, more hydrocarbon volatiles are driven off leaving a weaker char. The condensers 31 and 33 can use flowing water from cooling tower 35 as a coolant to condense out the volatiles.

Gas from tank 59 can flow through line 60A to power the generator 67 that can provide electricity to power the operation. While the generator 67 uses some fuel, the process 100 will generate an excess of fuels and hydrocarbon products stored in tanks 45, 49, 53 and 59. Fuel from tank 59 can also power a gas fired boiler 61 that can heat water in tanks 63 and 65 for a building (not shown) and for manufacturing operations such as the washer 9. The fuel will also be used for the pre-heat process 23 and processor 27.

FIG. 2 shows a flow chart of the steps that can take place in the processor programmable controller 71. The process 300 includes first the step of prepping 302 the tire material 104. Prepping 302 might include collecting and culling the tires to pull out those that might be re-treaded, prepping 302 might also include removing the metal bead from the tire material 104, shredding in shredder 5. Prepping can include washing 304 the tires 104 to remove dirt in raw material washer 9, it can also include pre-heating 306 the tire material 104 to a temperature higher than ambient but lower than might begin vaporization of any volatile, other than water, to minimize the time in processor 27. Preheat temperature might take the tire material 104 to a temperature in the range of 250-350 degrees F. under atmospheric pressure for example, pre-heating the tire material 104 and driving off any moisture. Preparing 302 might also include the step of shredding the tire material 104 in shredder 5 into smaller pieces again to facilitate the tire material 104 reaching a uniform target temperature as quickly as possible within the processor 27. Preparation might also include washing whole OTR tires and staging them on process carts 21.

Once the tire material 104 is prepped, the carts 21 are rolled into the processor 17 and the tire material 104 is weighed 310 using scale 28 shown in FIG. 1. The scale 28 is a large floor type scale capable of tracking the total weight of the carts 21. The total weight of tire material 104 is the total weight measured less that of the carts 21 which is known.

Based on the weight of tire material 104, a weight can be calculated for a specific volatile to be removed. For example, there may be a customer wishing to purchase all of the fuel oil that can be produced. So the weight of fuel oil that will come from the tire material 104 can be calculated 312. The process programmable control 71 can then flood processor 27 with an initial atmosphere 313 of carbon dioxide from generator 67 and set 314 the desired temperature and vacuum to optimize removal of fuel oil from the tire material 104 and the process control 71 can monitor the process. The first gas can be vacuumed off to condenser 31 shown in FIG. 1 to be condensed and stored in tank 45. Then a second heat can be set 320 to match a second desired target temperature higher than the first, the second target temperature might be set to drive off a second gas product 322 such as a higher grade fuel oil. Additional temperature targets can be set 326 to drive off additional products, the process 300 can continue until the temperature targets get high enough that all that is left is semi-activated carbon and other inorganic material originally in the material 104. At each new temperature target, the initial weight can be taken and a final desired target weight can be calculated or pressure can be used to monitor process progress and the temperature set is maintained until enough gas is taken off and the new lower target weight is achieved.

Finally, after the highest desired temperature is achieved the temperature in the processor 27 can be allowed to return to a lower temperature such that the carts 21 can be removed to recover 332 the resulting carbon char. The quality of the carbon char will depend upon the highest temperature set to recover volatiles. Cooling in the processor can be accelerated by flooding the processor 27 with cooled generator exhaust gas as a final atmosphere 331. For example, the processor 27 might reach a high temperature of 800-1200 degrees F. At those temperatures the processor 27 can not be opened without extreme fire hazard. Cooling from 1200 degrees could take a long dwell time, but the processor 27 can be flooded with cooled exhaust gas from generator 67, these gases might be cooled to 250-350 degrees prior to circulation into the processor 27. Once cooled below combustion temperatures, the processor 27 can be opened and carbon char can be recovered from carts 21.

The processor 27 when operated as shown in FIG. 2 has almost no atmospheric emissions except for carbon dioxide from the fuel to provide heat, yielding a very clean method of handling tire waste and other waste material.

FIG. 3 shows details of the processor 27 which includes an insulated outer housing 200 and a sealable door 202. Tires 104, which can include large off road tires are placed on wheeled carts 21 and rolled through an opening such as door 202 onto tracks or rails 206. The tires 104 are positioned vertically such that a head tube 210 will be positioned in the center of the tires 104. A burner 220 on the outside of the processor ignites gas which burns as it travels down the center of the heat tube 210. Details of the heat tube 210 and burner 220 are shown in FIG. 4. The cart 21 includes uprights 222. In loading the processor the tires 104 are first places over a bar 228 that can be lifted by a lift device such as fork lift (not shown) or crane and placed on the uprights 222. These large Off The Road (OTR) tires 104 can be too heavy to be handled manually, some weighing hundreds of pounds. Other chipped and whole tires can be placed on carts 21 and processed in a similar manner. Once on the cart 21 the tires 104 can be rolled along a track on the lower surface of the processor 27 such as rails 206 into the processor 27. A fixture loading cart 250 with rails aligned with rails 206 can be used to transfer the cart 21 in and out of the processor 27. In the processor 27 the organic material will be driven from the tires 104 and the steel bands inside the tires 104 will remain hanging on bar 228 for easy clean up. Some carbon char will remain on the steel bands while the rest will fall into basket 230 formed at the bottom of the cart 21. The center heat tube 210 provides heat to the center portion of the tires that accelerates their distillation. Additional heat tubes 240 heat the outside of the tires 104. A plurality of heat tubes 240 can surround the outside of the tires 104, experience has shown that 3 or 4 are sufficient to distribute the heat.

FIG. 4 shows details of the burner 220 and center heat tube 210. The burner 220 receives gas through a flexible looped gas line 402. It has been found that for the scale 28 to work properly all the connections to the processor 27 must be flexible and allow movement in all direction. The flexible looped gas line 402 provides one such flexible connection. Looped electrical connections 404 can also be used to provide enough wire to compensate for movement of the processor 27 in any direction. A removable burner tube 410 is located down the center of the center radiant heat tube 210 which includes an outer shell 412 which transfers radiant heat from the burner tube 410 to the processor 27 without allowing open flames in the interior of the processor 27. An expansion guide 414 supports the end of the burner tube 410 but allows for some movement of the burner tube 410 relative to the heat outer shell 412. Removing the bolts 420 allows the burner tube 410 to slide out of the shell 412 for service or replacement. The arrows in FIG. 4 show the direction of air flow through the burner 220 and center heat tube 210. Air is mixed with gas in the burner 220 and ignited. The mixture flows down through burn tube 410 and then through venture 424 and the flow of gas is reversed at air flow end plate 426 which has a curved shape to aid in flow reversal. The flow end plate 426 is mounted in an unsupported end 428 of the central radiant heat tube 210. The flow direction is changed 180 degrees and flow then travels in the shell between the tube 410 and the heat outer shell 412 where heat is transferred to the processor 27. Thus the radiant heat tube 210 contains a duel pass burner system that allows the cart 21 to easily roll through the open door and into and out of the processor 27 without interference. Exhaust gas then exits the processor through flue 450 which is connected to an exhaust stack 454 by flue expansion joint 452. The exhaust stack 454 will include a fixed support 456 such as a connection to a building containing the processor 27 so then expansion joint 452 is required to allow the scale 28 to function properly. The expansion joint includes a first pipe 460 carrying gas into the joint 452, and enlarged pipe section 462 having a packing material that insulates and prevents exhaust leak and the joint then connects to a fixed exhaust stack 454 connected to a fixed structure 456 such as a building. As can be seen in FIG. 3 the heat radiating from the surface of heat outer shell 412 goes directly to the inside of the tires 104 which aids in rapid decomposition of the tires 104.

FIG. 5 shows an end view of the processor 27 with the door 202 removed. Arrows indicate a direction of flow as vacuum is applied through connections 502. Organic material in gas form from the tires 104 fills the processor 27 and is drawn out through outlets 510. The gas flows into cylindrical condenser tubes 512 that line the exterior of the processor 27. These cooling condenser tubes allow some of the gas to begin to cool and condense into liquid. Liquids will flow down through the condenser and exit at flexible oil pipe connections 514 while lighter gas that does not condense will be evacuated through upper flexible vacuum pipe connections 516. The connections 514, 516 might be braided cable for example and can be placed at an angle such as 45 degrees shown, this allows for movement of the processor 27 in any direction relative to fixed supports such as floor ‘F’ and tube supports 520 for example. The processor 27 can be supported by any support such as scale 28. Alternatively the processor might be used without the scale 28 or the scale 28 might be used to weigh the tires 104 at the start and end of the process. FIG. 5 also shows an end view of the center radian heat tube 210 and the other heat tubes 240. The heat tubes 240 can be spaced around the exterior of the tire 104 shown in phantom lines and the tire centers are located over the central radiant tube 210. It has been found that an arrangement of three tubes 240 spaced around the tire 240 at approximately 120 degree spacing plus the center radiant tube 210 provides coverage of the tire 104 such that rapid and complete decomposition occurs. However additional heating tubes may be warranted to further accelerate the process.

Giant OTR tires may weight up to 14,000 pounds with even larger tires under development. Presently, the only legal way to dispose of giant OTR tires is to cut them into smaller pieces and deposit the flattened material in a landfill or monofill or to store them in the mines or quarries were they are generated, neither of which is environmentally friendly. There is also some minor use of giant OTR tires for agricultural purposes but the tire still remains a disposal problem when the use is over. The processors described above are particularly adapted for use with smaller tires while the processors described below are adapted for use in disposing of giant OTR tires in an environmentally friendly manner.

A vertically loaded processor 627 for giant whole OTR tires is schematically illustrated in FIGS. 6 and 7. Except where noted processor 627 is similar to processor 27 as described above and operates in a similar manner. Processor 627 includes a insulated housing 629 and an open top which is sealed with a hinged or removable door 631. Processor 627 may be round, rectangular or otherwise shaped. As illustrated processor 627 is supported on legs 633 above floor F.

A central radiant heat tube 635 is supported on bottom 637 with an unsupported end adjacent door 631. Air is mixed with gas in a burner 639 outside processor 627 and ignited. The hot combustion gases are passed through an insulated radiant heat tube 641 to central radiant tube 635. The mixture flows up through a burn tube 643 and is then reversed at air flow end plate 645 which has a curved shape to aid in flow reversal. Air flow end plate 645 is mounted on unsupported end of central radiant heat tube 635. The flow direction is changed 180 degrees for nonlaminar, turbulent flow for more efficient heat transfer to processor 627. Exhaust gas from central radiant heat tube 635 exits processor 627 through an insulated exhaust tube 647 and then a flue as described with respect to processor 27 and shown in FIG. 4.

A plurality of peripheral heat tubes 649 are positioned and fixed in space with respect to each other around and spaced from central radiant heat tube 635. As best seen in FIG. 7, peripheral heat tubes 649 are formed as a loop with first end serving as inlet leg 651 and a second end serving as an outlet leg 653. Inlet leg 651 of each peripheral heat tube 649 is connected to a burner 655 through which hot combustion gases are supplied and an exhaust 657 through which the gases exit processor 627. While separate burners are illustrated for each peripheral heat tube 649, the peripheral heat tubes may be connected through a manifold (not shown) to a single burner. The direction of flow of the combustion gases in adjacent peripheral heat tubes 649 is in opposite directions with a temperature gradient from inlet end 651 to outlet end 653. By positioning inlet end 651 spaced from but adjacent to outlet end 653 of another peripheral heat tube 649 the utilization of the available radiant heat within processor 627 is maximized. The tube temperature of the inlet portion 651 exerts thermal influence on the temperature of the outlet portion 653 and dictates the spacing necessary between adjacent peripheral heat tubes 649 in order to reduce the inhomogeneities of temperature in the peripheral heat tubes 649 within processor 627, i.e., to optimizes the homogeneity of the radiant heat tube surface. This in turn maximizes to the extent possible the homogeneity of the radiant heat energy applied to tires 659 in processor 627.

With continuing reference to FIGS. 6 and 7, a plurality of vapor removal outlets 661 are provided in processor 627. Valves 663 are provided in outlets 661. Controller 300 may be programmed to selectively open and close valves 663 in response to temperature sensors 665 provided in processor 627 to equalize the temperature and to prevent hot spots. Exhaust gases pass into a plenum 666 for processing as described in connection with FIG. 5.

A removable basket or process fixture 667 may be provided into which giant whole OTR tires 659 may be stacked. Basket 667 may be lifted with a crane (not shown) or other lifting device in and out of processor 627 when door 631 is open. As basket 67 is lifted in, tires 659 pass over central radiant heat tube 635 such that it is located in a central opening of each tire. A bead support fixture 669 may be provided on basket 667 to keep the tire rim from closing during processing.

Turning now to FIGS. 8 and 9 a horizontally loaded processor 727 for giant whole OTR tires is schematically illustrated. Processor 727 differs from processor 627 in that door 729 is in a sidewall and that tires 731 may be loaded on a cart 733 and rolled into the processor on rails 735. Functionally, however, processor 727 operates in a similar manner with a central radiant heat tube 737 with an unsupported end adjacent door 729 and a supported end on a wall 739 opposite the door. A plurality of peripheral radiant heat tubes 741 are also arranged around and spaced from central radiant heat tube 737.

As best seen in FIG. 9, peripheral radiant heat tubes 741 are in the form of a U-shaped coil with an inlet leg 742 and a central bend which merges into an outlet leg 743. Peripheral radiant heat tubes 741 are positioned within processor 727 such that an inlet leg of any one of the plural tubes is immediate adjacent and spaced apart from an outlet leg of another one of the plural peripheral radiant heat tubes. This spacial pairing of an inlet leg of one tube with an outlet leg of another tube maximizes utilization of the available radiant heat within processor 727 as described above in connection with processor 627.

Flexible connections for materials flowing into and out of processor 627 and 727 are provided such that the weight of the processor may be accurately tracked with strain gauges 28 as discussed in connection with processor 27 and the process thereby monitored. By-products and waste may be also be treated as described with respect to processor 27. While processors 627 and 727 are adapted for use in recycling whole giant OTR tires, they may be scaled for use with smaller tires and may be used for recycling shredded material if desired.

Though modifications and changes may be suggested by those skilled in the art, it is the intention of the inventor to embody within the patent warranted hereon all changes and modifications covered by the attached claims. 

What is claimed:
 1. A processor for vacuum distillation of tires including: an insulated housing having an opening on one end, a cover over said opening, a plurality of peripheral heat tubes arranged around and spaced from a central radiant heat tube, said central radiant heat tube having an unsupported end adjacent said door and a supported end on a wall opposite said opening such that tires loaded through said opening will pass over said central radiant heat tube such that said central radiant heat tube is located in a central opening of each tire, said plurality of peripheral heat tubes each having an inlet leg and an outlet leg, said peripheral heat tubes being positioned and fixed in space with respect to each other such that the inlet leg of each peripheral heat tube is immediately adjacent to the outlet leg of an another peripheral heat tube whereby utilization of the radiant heat energy from the peripheral heat tubes maximized.
 2. The processor of claim 1 wherein a plurality of vapor removal outlets are arranged around and spaced from the central heat tube to minimize hot spots in the processor.
 3. The processor of claim 1 further including a basket in which tires may be arranged horizontally and lifted in and out of the processor through the opening when the door is open.
 4. The processor of claim 2 wherein a bead support fixture is provided on the basket for supporting the bead of the tires.
 5. The processor of claim 1 further including a cart on which tires may arranged vertically and rolled in and out of the processor through the opening when the door is open.
 6. The processor of claim 1 wherein said central radiant heat tube includes an inner heat tube for carrying burning gases in a first direction toward said door and an outer shell for carrying said gases in an opposite direction away from said door.
 7. The processor of claim 2 wherein said processor includes at least one vacuum source to draw gases from said housing through the vapor removal outlets.
 8. The processor of claim 6 wherein said central radiant heat tube includes a burner mounted on an end of said central radiant heat tube and wherein gases from said burner flow in said first direction toward said door and then said gases reverse flow adjacent said door and flow back toward said burner.
 9. The processor of claim 6 wherein said outer shell of the central radiant heat tube is connected to an exhaust flue and said exhaust flue includes a flexible joint, said flexible joint including a first exhaust pipe, a second exhaust pipe and an insulated coupling allowing relative movement between said first and second pipe without allowing leakage from said exhaust and further wherein said processor rests on a scale for weighing said processor before and during processing of said tires.
 10. A processor for vacuum distillation of tires including an insulted housing having an opening on one end, a door over said opening, a plurality of peripheral heat tubes arranged around and spaced from a central radiant heat tube, said central radiant heat tube having an unsupported end adjacent said door and a supported end on a wall opposite said opening such that tires loaded through said opening will pass over said central radiant heat tube such that said central radiant heat tube is located in a central opening of each tire, said plurality of peripheral heat tubes each having an inlet leg and an outlet leg, said peripheral heat tubes being positioned and fixed in space with respect to each other such that the inlet leg of each peripheral heat tube is immediately adjacent to the outlet leg of an another peripheral heat tube whereby utilization of the radiant heat energy from the peripheral heat tubes maximized, and a scale supporting said processor.
 11. The processor of claim 10 wherein the central radiant heat tube is connected to an exhaust flue and said exhaust flue includes a flexible joint, said flexible joint including a first exhaust pipe, a second exhaust pipe and an insulated coupling allowing relative movement between said first and second pipe without allowing leakage from said exhaust.
 12. The processor of claim 10 wherein the door is in a top of the housing and further including a basket in which tires may be arranged horizontally and lifted in and out of the processor through the opening when the door is open.
 13. The processor of claim 12 wherein a bead support fixture is provided on the basket for supporting the bead of the tires.
 14. The processor of claim 10 wherein the door is in a sidewall of the housing and further including a cart on which tires may arranged vertically and rolled in and out of the processor through the opening when the door is open.
 15. The processor of claim 10 wherein a plurality of vapor removal outlets are arranged around and spaced from the central heat tube to minimize hot spots in the processor.
 16. The processor of claim 15 wherein said processor includes at least one vacuum source to draw gases from said housing through the vapor removal outlets. 